JP3773991B2 - Information recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information recording medium.To the bodyIn particular, high-density information recording media with a narrow track pitchTo the bodyRelated.
[0002]
[Prior art]
As a high-density type information recording medium having a narrow track pitch, for example, as described in JP-A-6-176404, a guide groove (hereinafter referred to as “group”) of an optical disc, There is known an information recording medium for recording information on both of the sandwiched convex portions (hereinafter referred to as “land”).
[0003]
In this information recording medium, a pair of a groove and a land is used, and a prepit is arranged on a virtual extension line at the boundary between the pair of the groove and the land. Address information (ID number) indicating a recording area is assigned to this pre-pit, and by sharing the address information for a pair of lands and groups in one pre-pit, the recorded information is shared with both lands and groups. I try to record.
[0004]
[Problems to be solved by the invention]
However, in the conventional information recording medium, the address information for the pair of lands and the group is shared by one pre-pit. Therefore, even when the address information can be read correctly during reproduction, the land portion corresponding to this address information is used. There is a problem that it is not possible to distinguish between the sector and the sector of the group part.
[0005]
If the land portion and the groove portion cannot be distinguished, for example, an impact is applied to the recording / reproducing apparatus during information writing (WR), causing a track deviation, and the laser from the land sharing the same pre-pit ID to the laser is generated. Even if the spot moves, this cannot be detected.
[0006]
Also, if the land and group instructions are set in reverse due to a failure of the recording / reproducing device or a design error of the microprocessor (MPU) software, the address information on the information recording medium An error cannot be detected. For example, when a land is mistakenly positioned in a group during reproduction of a land, a group sharing the same address part as this land is reproduced, and data different from that requested by the host device is transferred. . Similarly, when the land is mistakenly positioned in the group, the data is recorded in the group sharing the same ID as the land, and the data is already recorded in the group. In some cases, double writing is performed, and previously recorded data is destroyed.
[0007]
The above problems are not limited to the case where the address information for a pair of lands and groups is shared by a single pre-pit. In an information recording medium with a narrow track pitch and high density, the boundary between a pair of tracks This also occurs when prepits are arranged on a virtual extension line of a part and the address information of a pair of tracks is shared by one prepit. That is, even when the address information of a pair of tracks is shared by a single prepit, there is a problem that even if the address information can be read correctly during reproduction, the pair of tracks corresponding to the address information cannot be distinguished.
[0008]
An object of the present invention is an information recording medium that is a high-density type with a narrow track pitch and that can distinguish between tracks.BodyIt is to provide.
[0009]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention provides an information recording medium comprising a plurality of sectors in a land track and a groove track, wherein the plurality of sectors have an address information area and a data area, and the address information The region has a plurality of address portions, and the plurality of address portions are provided with a first address portion provided at a boundary portion between the right and left adjacent land tracks and groove tracks, and the address portion. And a second address portion provided at a boundary portion adjacent to the left and right adjacent to the boundary portion between the left and right land tracks and the groove track, and the first address portion and the second address portion are provided in the plurality of address portions. Each of the two address portions has the same address as the portion in which information indicating the position of the own sector among the plurality of sectors is recorded. From other address portion included in the less information area has a portion in which information for identifying the own address portion is recorded,A first land track, a first groove track adjacent to the first land track, a second land track adjacent to the first groove track, and a second land track adjacent to the second land track. In the groove trackIn the plurality of address parts,Provided at the boundary between the first land track and the first groove trackInformation indicating the position of the own sector in the first address portionAnd provided at a boundary portion between the first groove track and the second land track.Information indicating the position of the own sector in the second address portion;The information indicating the position of the own sector in the first address portion provided at the boundary between the second land track and the second groove track is sequentiallyInformation indicating that the track differs by one trackIn the newsYes, such a configuration makes it possible to distinguish tracks.
[0010]
In the information recording medium, preferably,A plurality of the first address portion and the second address portion are provided in the same address information area.It is what I did.
[0011]
In the information recording medium, preferably,The land track and groove track are divided into a plurality of tracks in the radial direction of the own information recording medium, and each of the plurality of tracks is divided into N sectors in the circumferential direction of the own information recording medium. ingIt is what I did.
[0012]
In the information recording medium, preferably, the portion in which the information indicating the position of the own sector is recorded includes a track information portion in which information indicating a position in the radial direction of the own information recording medium is recorded, and the own information recording And a sector information section in which information indicating the circumferential position of the medium is recorded.
[0013]
In the information recording medium, preferably, the address information area is recorded in a plurality of prepits.
[0014]
In the information recording medium, preferably, the plurality of address portions are recorded in a plurality of prepits provided at a boundary portion between adjacent land tracks and groove tracks adjacent to the left and right.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an information recording medium and a recording / reproducing apparatus using the same according to an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is an explanatory diagram of a recording track of an optical disc that is an information recording medium according to an embodiment of the present invention.
The optical disk in this embodiment is a two-spiral land / group recording optical disk. The optical disc may be any of a phase change type, a write once type, or a magneto-optical type.
[0018]
On the surface of the disk-shaped optical disc 10, a concave groove 4 serving as a guide groove for tracking control is formed in a spiral shape. Between the spiral grooves 4, convex-shaped lands 5 are formed in a spiral shape. Accordingly, the groove 4 and the land 5 are in a two-spiral form in which the spiral shape is formed. Groove 4 and land 5 are land / tracks used as recording tracks TR- (N-2), TR- (N-1), TR-N, TR- (N + 1), and TR- (N + 2) for recording information, respectively. This is a group recording method. Each track TR is divided in the circumferential direction, and is composed of N sectors SEC-1, SEC-2, SEC-3, ..., SEC- (N-1), SEC-N.
[0019]
Next, the detailed configuration of the pre-pits of the optical disc will be described with reference to FIG. FIG. 2 is a partially enlarged view of the vicinity of the prepit portion on the surface of the optical disc according to the embodiment of the present invention.
[0020]
A track on the optical disc is divided into a data portion 1 and an ID portion 2 in the circumferential direction. The ID part 2 and the data part 1 following the ID part 2 constitute one sector SEC shown in FIG. In the data portion 1, convex-shaped lands 4 and concave-shaped grooves 5 are alternately arranged in the radial direction of the optical disc, and a recording mark is recorded in both the land 4 and the grooves 5. -6 is recorded. That is, the land 4 and the group 5 are both recording areas.
[0021]
No groove (concave portion) is formed in the ID portion 2, and the prepit 7 is arranged on a virtual extension line at the boundary between the land 4 and the group 5. The pre-pit 7 is always arranged on a virtual extension line at the boundary between the land 4 and the group 5. The ID unit 2 includes an ID1 unit 301, an ID2 unit 302, and a sector mark unit 305. The prepit 7 is arranged at the lower side in the figure with respect to the center line of the land 4 in the ID1 portion 301 and the sector mark 305, and is arranged at the upper side in the drawing with respect to the centerline of the land 4 in the ID2 portion 302. Yes. The ID1 portion 301 and the ID2 portion 302 are arranged at different positions in the circumferential direction (track direction) of the optical disc.
[0022]
The ID1 unit 301 and the ID2 unit 302 include a VFO unit 306, a synchronization mark 307, an address number 312 and a CRC unit 311, respectively. The VFO unit 306 records a repetitive pattern for generating a reproduction clock synchronized with the reproduction signal from the recording medium. In the synchronization mark 307, a predetermined pattern indicating the start position of the address number 312 is recorded.
[0023]
The address number 312 includes a track number 308, an ID identification number 309, and a sector number 310. Information indicating the position in the radial direction of the optical disk is recorded in the track number 308. Information for identifying the ID 1 part 301 and the ID 2 part 302 is recorded in the ID identification number 309. As the ID identification number 309, for example, “0” is recorded in the ID 1 part 301 and “1” is recorded in the ID 2 part 302. In the sector number 310, information indicating the circumferential position of the track is recorded.
[0024]
The same track number is recorded in the track number 309 of the ID1 portion 301 and the ID2 portion 302 of the land 4. That is, for example, the track number “1” is recorded in the ID 1 portion 301 of the track number 1 land 203, and the same track number “1” is recorded in the ID 2 portion 302.
[0025]
On the other hand, the ID1 part 301 of the group 5 shares the prepit 7 with the upper land 4 in the figure, and the ID2 part 302 shares the prepit with the lower land 4 in the figure. Accordingly, the track numbers of the ID1 portion 301 and the ID2 portion 302 of the group 5 are different, and the track numbers are the most different. That is, for example, the track number “0” is recorded in the ID1 portion 301 of the track number 0 group 202, and the different track number “1” is recorded in the ID2 portion 302.
[0026]
As described above, in the present embodiment, the ID1 part and the ID2 part are arranged at the boundary between adjacent tracks and at different positions in the track direction. That is, a pre-pit including an ID1 portion is provided on the extended line between the land and the adjacent right and left adjacent grooves, and similarly, the ID2 portion is provided on the extended line between the groove and the adjacent land. Including prepits. Further, both the land and the groove are arranged so that no pre-pit exists on both sides of the same position. Thus, by arranging prepits on both sides of the land and both sides of the group to reduce the track offset and disposing no prepits at the same position, crosstalk can be reduced.
[0027]
According to the information recording medium according to the present embodiment, tracks can be distinguished.
[0028]
In addition, the track offset can be reduced and the crosstalk can be reduced.
[0029]
Next, an optical disc apparatus according to an embodiment of the present invention will be described with reference to FIG.
FIG. 3 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to an embodiment of the present invention.
[0030]
During reproduction of the ID unit 2, the laser light emitted from the laser light source 57 is irradiated onto the optical disk 10, and the reflected light is received by the light receiving unit 58. The laser light source 57 and the light receiving unit 58 constitute an optical head unit. The light receiving unit 58 detects the prepit pattern shown in FIG. 2 formed in advance on the optical disc 10 as a change in the intensity of the reflected light, and detects this as a signal. Although not shown here, after the light receiving unit 58, an AGC (Auto Gain Control) unit that automatically adjusts the output of the preamplifier unit that amplifies the detected weak signal to a predetermined amplitude, an AGC unit A PLL unit for generating a reproduction clock synchronized with the output signal is provided. The output signal of the light receiving unit 58 is processed by the preamplifier unit, the AGC unit, and the PLL unit to become the reproduction signal 31. As the reproduction signal 31, a pulse signal corresponding to the prepit 7 formed in advance in the ID portion 2 is reproduced.
[0031]
The reproduction signal 31 is sent to the demodulation circuit 75, the ID1 detection circuit 59, the ID2 detection circuit 60, and the sector mark detection circuit 61.
The sector mark detection circuit 61 detects the head sector mark 305 of the ID section 2 at the head of each sector, and controls a sector mark detection signal 81 which is a pulse signal indicating the detection timing of the sector mark 305. The data is sent to the la unit 801.
[0032]
The controller unit 801 outputs a sector pulse 33 for outputting a pulse by the VFO unit 306 in the ID1 unit 301 of the reproduction signal 31 with reference to the timing of the sector mark detection signal 81. The ID1 detection circuit 59 and the ID2 detection circuit 60 are reset by the sector pulse 33 output from the controller unit 801.
[0033]
In addition, the controller unit 801 includes an ID1 detection gate signal 77 which is a gate signal that becomes “H” level in the areas of the synchronization mark 307, the address number 312 and the CRC unit 311 in the ID1 unit 301. In the ID2 unit 302, the synchronous mark 307, the address number 312 and the ID2 detection gate signal 78 which is a gate signal which becomes "H" level in the area of the CRC unit 311 are output.
[0034]
The ID1 detection circuit 59 detects the track number 308 in the ID1 portion 301 from the reproduction signal 31 input from the light receiving portion 58 during the period when the ID1 detection gate signal 77 output from the controller portion 801 is at the “H” level. And the sector number 310 are detected, and the ID1 number detection value 68 is output to the comparison circuit 62. Further, the ID2 detection circuit 60 detects the track number in the ID2 unit 302 from the reproduction signal 31 input from the light receiving unit 58 during the period when the ID2 detection gate 78 output from the controller unit 801 is at the “H” level. 308 and the sector number 310 are detected, and an ID2 number detection value 69 composed of the track number and the sector number is output to the comparison circuit 63.
[0035]
The controller 801 outputs the track number and sector number of a sector for executing processing such as reproduction, recording, or erasing to the comparison circuit 62 as an ID1 number instruction value 70, and also compares it as an ID2 number instruction value 71. To 63. The comparison circuit 62 matches the ID1 number detection value 68 and the ID1 number instruction value 70 for each bit, and outputs an ID1 detection signal 79 that is at the “H” level when all the bits match. The comparison circuit 63 matches the ID2 number detection value 69 and the ID2 number instruction value 71 for each bit, and outputs an ID2 detection signal 80 of “H” level when all bits match.
[0036]
The ID1 detection signal 79 output from the comparison circuit 62 and the ID1 detection signal 80 output from the comparison circuit 63 are input to the AND gate 64. The ID detection signal 72 that is the output of the AND gate 64 is at the “H” level when both the ID1 detection signal 79 and the ID2 detection signal 80 are at the “H” level. The ID detection signal 72 is sent to the controller 801, and reports that the ID of the sector that performs processing such as reproduction, recording, or erasing has been detected.
[0037]
When executing the reproduction process, the demodulation circuit 75 demodulates the reproduction signal 31 of the user data recorded by applying a predetermined modulation to the data unit 1 on the optical disk 10 and the demodulated signal 76 is controlled by the controller. Send to 801. During the period in which the ID detection signal 72 is at “H” level, the controller 801 reads the input demodulated signal 76 as user data of the sector that executes the reproduction process, and outputs it to the outside.
[0038]
Further, when the recording process is executed, the controller 801 is “H” in the data portion of the WR data signal 65 which is data to be recorded on the optical disc 10 and the reproduction signal 31 when the recording or erasing process is executed. A WR gate signal 66, which is a gate signal indicating the recording area, is sent to the AND gates 54 and 53, respectively.
[0039]
On the other hand, when a sector for executing the recording process is detected, an ID detection signal 72 output from the AND gate 64 is sent to the AND gates 53 and 54. Therefore, when the WR gate signal 66 is "H" level and the ID detection signal 72 is "H" level, the AND gate 53 outputs the "H" level coincidence signal 67, and the AND gate 54 When the ID detection signal 72 is at “H” level, the data signal 55 synchronized with the WR data signal 65 is output.
[0040]
The laser light source driving circuit 56 is controlled by the output signals 55 and 67 of the AND gates 54 and 53, and strengthens the laser power of the laser light source 57 at the timing of recording the recording mark. Make a record.
[0041]
At the time of erasing, the laser light source driving circuit 56 is controlled by the output signals of the AND gates 54 and 53, and at the timing of erasing, the laser power of the laser light source 57 is strengthened and erasing is performed. Do.
[0042]
At the time of reproduction of ID or data, data to be recorded is not output to the WR data 65, and the WR gate 66 is turned off, whereby the laser light source driving circuit 56 is recorded. Alternatively, the laser light source 57 emits light that is relatively weaker than that at the time of erasing.
[0043]
A controller 801 is provided with a modulation circuit that performs predetermined modulation on the user data, and outputs the modulated data as WR data 65. As a modulation method, 1-7 RLL (Run Length Limit) modulation, 2-7 RLL modulation, or the like may be used. However, the modulation circuit inside the controller 801 and the demodulation circuit 75 are configured to correspond to the same modulation method.
[0044]
Next, the ID1 number instruction value 70 and the ID2 number instruction value 71 output from the controller 801 will be described.
As described in FIG. 2, the track number 309 of the ID 1 portion 301 and the ID 2 portion 302 of the land 4 is recorded with the same track number, whereas the ID 1 portion 301 and the ID 2 portion 302 of the group 5 are recorded. In the track number 309, different track numbers are recorded. Accordingly, when data recording, reproduction, and erasing processing is performed on the land 4 and when processing is performed on the groove 5, the ID1 number instruction value 70 and the ID2 number instruction value 71 are set. Need to be different.
[0045]
Therefore, in the process for the land 4, the same track number corresponding to the land to be processed is set in the ID1 number instruction value 70 and the ID2 number instruction value 71. In the process for group 5, different track numbers corresponding to the group to be processed are set in ID1 number instruction value 70 and ID2 number instruction value 71, respectively. In this case, the track number of the ID2 portion 302 is set to a value larger by one track than the track number of the ID1 portion 301 in correspondence with the ID portion 2 shown in FIG.
[0046]
That is, for example, when processing is performed for the track number 1 land 203 shown in FIG. 2, the track number “1” is set as the ID1 number indication value 70 and the same track number “1” is set as the ID2 number indication value 71. Further, in the process for the track number 1 group 204 shown in FIG. 2, the track number “1” is set as the ID1 number indication value 70 and the track number “2” is set as the ID2 number indication value 71.
[0047]
The comparison circuit 62, the comparison circuit 63, and the AND gate 64 detect that these indicated values and the reproduced ID1 number detection value 68 and ID2 number detection value 69 coincide with each other for ID1 and ID2, and this is detected. As a condition, the controller 801 executes processing.
[0048]
As the configuration of the ID1 detection circuit 59 and the ID2 detection circuit 60, for example, the ID1 detection gate signal 77 and the ID2 detection gate signal 78 are reset during the “L” level period, respectively, and the reproduction data is displayed. A shift register that sequentially captures each bit, and a mark detection circuit that detects a synchronous mark 307 by a pattern matching method from the output of each bit of the shift register and outputs a pulse signal indicating the detected timing In response to this pulse signal, the subsequent address number 312 starts to be fetched, and after fetching, the register number is held and reset by the sector pulse 33. When the address number 312 is recorded on the optical disc after being subjected to predetermined modulation, a demodulating circuit may be provided so that the demodulating circuit can take in the register number.
[0049]
Further, although the ID1 detection circuit 59 and the ID2 detection circuit 60 are described as separate blocks in FIG. 3, the present invention is not limited to this, and some circuits may be shared. That is, a shift register for sequentially reading reproduction data bit by bit, and a sync mark 307 is detected from the output of each bit of the shift register by a pattern matching method, and a pulse signal indicating the detected timing is output. When the mark detection circuit to perform and the ID1 detection gate 77 are at the “H” level, the subsequent address number 312 is started to be fetched by the pulse signal, held after being fetched, and When the register circuit for ID1 reset by the sector pulse 33 and the ID2 detection gate 78 are at the “H” level, the subsequent address number 312 starts to be fetched by the pulse signal, and after this, And a register circuit for ID2 that is reset by the sector pulse 33 may be used.
[0050]
In short, the ID1 unit 301 and the ID2 unit 302 may be configured in any manner as long as the circuit detects each address number by distinguishing the ID1 unit 301 and the ID2 unit 302 from each other.
[0051]
Next, the operation of the optical disc apparatus according to the embodiment of the present invention will be described with reference to FIG.
FIG. 4 is a time chart at the time of recording in the optical disc apparatus according to the embodiment of the present invention.
[0052]
FIG. 4 is an enlarged view of the timing of the ID part when recording is performed on the sector of sector number “4” of the track number 1 group 204 of the optical disk shown in FIG.
[0053]
FIG. 4A shows a reproduction signal 31 in which the output signal of the light receiving unit 58 shown in FIG. 3 is processed by the preamplifier unit, the AGC unit, and the PLL unit. As the reproduction signal 31, a pulse signal corresponding to the prepit 7 formed in advance in the ID portion 2 is reproduced. That is, the reproduction signal 31 is composed of the sector mark 305, the VFO unit 341, the synchronization mark 342, the address number 343, and the ID1 unit 301 including the CRC unit 344, the VFO unit 345, the synchronization mark 346, the address number 347, and the CRC unit. It consists of an ID1 part 302 composed of 348 and a data part 1. When information is recorded in advance in the data portion 1, a signal corresponding to the recorded information is output.
[0054]
FIG. 4B shows a sector mark detection signal 81 output from the sector mark detection circuit 61 shown in FIG. The sector mark detection circuit 61 detects the sector mark 305 in the reproduction signal 31 and outputs a pulse signal to the sector mark detection signal 81.
[0055]
FIG. 4C shows the sector pulse 33 output from the controller 801 shown in FIG. The controller 801 outputs a pulse signal to the sector pulse 33 in the vicinity of the VFO unit 341 using the detection pulse of the sector mark detection signal 81 as a reference.
[0056]
FIG. 4D shows a gate signal ID1 detection gate signal 77 output from the controller 801 shown in FIG. The controller 801 outputs an ID1 detection gate signal 77 which becomes “H” level in the areas of the synchronous mark 342, the address number 343 and the CRC unit 344 with reference to the detection pulse of the sector mark detection signal 81.
[0057]
FIG. 4E shows a gate signal ID2 detection gate signal 78 output from the controller 801 shown in FIG. The controller 801 outputs the ID2 detection gate signal 78 which is at the “H” level in the synchronous mark 346, address number 347, and CRC area 348 with reference to the detection pulse of the sector mark detection signal 81.
[0058]
FIG. 4F shows the ID1 number detection value 68 detected by the ID1 detection circuit 59 shown in FIG. The ID1 detection circuit 59 is reset by the sector pulse 33 output from the controller 801. As the ID1 number detection value 68 when reset by the sector pulse 33, for example, as shown in FIG. 4, a track number “0” and a sector number “0” may be set. Since the ID may be erroneously detected at the time of executing the processing of the sector of “0” and sector number “0”, it is more desirable to set the track number and the sector number to a number that cannot exist on the optical disc.
[0059]
The ID1 number detection value 68 is reset by the pulse signal of the sector pulse 33, and then reads the address number 343 of the ID1 part during the period when the ID1 detection gate signal 77 is at the “H” level, and is the value thereof, for example, , Track number “1” and sector number “4” are set and held until the timing of the pulse signal of the sector pulse 33 of the next sector.
[0060]
FIG. 4G shows an ID2 number detection value 69 detected by the ID2 detection circuit 60 shown in FIG. After being reset by the sector pulse 33 output from the controller 801, the ID2 detection circuit 60 reads the address number 347 of the ID2 section during the period when the ID2 detection gate 78 is at “H” level, and the value is, for example, the track number “2” and sector number “4” are set and held until the timing of the pulse signal of the sector pulse 33 of the next sector.
[0061]
FIG. 4H illustrates a setting state of the ID1 number instruction value 70 output from the controller 801 illustrated in FIG. The controller 801 sets the address of the sector to be processed as the ID1 number indication value 70 with reference to the detection pulse of the sector mark detection signal 81. When processing for one sector is performed, the setting timing is set to the timing before the address number 343 of the sector to be processed is reproduced. When processing a plurality of sectors in succession, the first address number of the sector to be processed is set first, and after the first sector is processed, the sector number is determined at the sector pulse timing from the second sector onward. Is incremented by one.
[0062]
FIG. 4I shows the setting state of the ID2 number instruction value 71 output from the controller 801 shown in FIG. 3, and is set in the same manner as the ID1 number instruction value 70.
[0063]
In the example shown in FIG. 4, in order to record in the sector with the sector number “4” of the track number 1 group 204, the track number “1” and the sector number “4” are set as the ID1 number indication value 70. As the ID2 number instruction value 71, a track number “2” and a sector number “4” are set.
[0064]
FIG. 4J shows the ID1 detection signal 79 output from the comparison circuit 62 shown in FIG. When the track number “1” and the sector number “4” are set in the ID1 number detection value 68, the ID1 detection signal 79 coincides with the ID1 number indication value 70 and becomes “H” level.
[0065]
FIG. 4K shows the ID2 detection signal 80 output from the comparison circuit 63 shown in FIG. When the track number “2” and the sector number “4” are set in the ID2 number detection value 69, the ID2 detection signal 80 coincides with the ID2 number instruction value 71 and becomes “H” level.
[0066]
FIG. 4L shows an ID detection signal 72 output from the AND gate 64 shown in FIG. When the address numbers 343 and 347 of both the ID1 part 301 and the ID2 part 302 of the sector to be processed are correctly reproduced, both the ID1 detection signal 79 and the ID2 detection signal 80 are areas including all subsequent data parts. The ID detection signal 72 generated by taking the logical product of both is also at the “H” level.
[0067]
FIG. 4M shows WR data 65, which is user data after modulation to be recorded, output from the controller 801 shown in FIG.
[0068]
FIG. 4N shows a gate signal 66 indicating a recording area output from the controller 801 shown in FIG.
[0069]
When recording and when the ID detection signal 72 is at "H" level, the AND gates 54 and 53 are turned on, and the WR data 65 and the WR gate 66 are shown in FIGS. As shown in (P), the data is output to the AND gate output 55 and the AND gate output 67, and the laser power is controlled by the recording power to perform recording.
[0070]
Although not shown in FIG. 4, during the reproduction process, if the ID detection signal 72 is at "H" level, the WR data 65 and the WR gate 66 are at "L" level, and the laser. Is controlled by the reproduction power, and the data recorded in the data section is transferred from the controller section 801 to the host computer or a host device such as a personal computer.
[0071]
As described above, in the optical disk as shown in FIG. 2, when either ID1 or ID2 cannot be reproduced correctly, the sector cannot be specified. In such a case, the ID detection signal 72 is at the “L” level. Thus, the demodulated data 76 is not transferred, and erroneous sector data is prevented from being transferred to the host device.
[0072]
In the erasing process, if the ID detection signal 72 is at "H" level, the WR data 65 and the WR gate 66 are at "H" level, and the laser has high power for erasing. The data recorded in the data section is erased.
[0073]
As described above, in the optical disk as shown in FIG. 2, when either ID1 or ID2 cannot be reproduced correctly, the sector cannot be specified. In such a case, the ID detection signal 72 is at the “L” level. This prevents erroneous erasure.
[0074]
Next, the operation when a defect occurs on the optical disc will be described with reference to FIGS.
FIG. 5 is a waveform diagram of a reproduction signal reproduced from the optical disc according to the embodiment of the present invention shown in FIG.
[0075]
In FIG. 5, a track number 0 land reproduction signal 211 schematically shows a signal reproduced from the track number 0 land 201 shown in FIG. 2, and a track number 0 groove reproduction signal 212 is shown in FIG. A signal reproduced from the track number 0 groove 202 is schematically shown. Other reproduction signals 213,..., 220 are also reproduction signals corresponding to the lands 203,..., 209 and grooves 204,.
[0076]
Here, for example, as shown in FIG. 2, when a defect 901 occurs in a part of the ID portion 2, as shown in FIG. 5, a waveform abnormality 921 is generated in the ID1 portion 301 of the track number 2 land reproduction signal 215. Occurs, and the address number of the ID1 portion 301 cannot be correctly reproduced. On the other hand, the track number “2” is reproduced from the ID2 portion 302 of the track number 2 land reproduction signal 215. This is the ID2 portion of the track number 1 group reproduction signal 214 obtained by reproducing the track number 1 group 204. This is the same value as the track number “2” of 302 and cannot be distinguished.
[0077]
If recording or erasure of the data section 1 following the ID section 2 of the track number 2 land 205 is performed only on condition that the value of the ID 2 section 302 matches the designated track number, the track number 1 group is mistakenly recorded. When the optical head is positioned on the groove 204, this cannot be detected, and the data already recorded in the data section 1 following the ID section 2 of the track number 1 group 204 is destroyed. Become.
[0078]
If the same thing occurs during data reproduction, the data in the data section 1 of the track number 1 group 204 different from the requested one is transferred.
[0079]
In order to prevent malfunctions due to defects formed on the optical disc, in this embodiment, as described in FIG. 3, ID1 and ID2 are individually detected by the detection gates, and both IDs are detected by the respective IDs. Processing such as recording, erasing, and reproduction is performed on condition that the value matches the instruction value.
[0080]
That is, in the present embodiment, when recording on the track number 2 land 205 of the optical disc shown in FIG. 2, the same track number “2” is set as the track number of the ID1 number indication value 70 and the ID2 number indication value 71. At this time, if the optical head is mistakenly positioned at the track number 1 group 204, the track number “2” is detected by the ID2 detection circuit 60, and the ID2 detection signal 80 becomes “H” level. On the other hand, the track number “1” is detected by the ID1 detection circuit 59. However, since the track number “2” is set in the ID1 instruction value 71, the comparison circuit 62 does not match, and the ID1 detection signal 79 is “L”. "Become level. The ID detection signal 72 at the output of the AND gate 64 that takes the logical product of both is also at the "L" level, reporting that the ID could not be detected normally to the controller 801, and in the AND gates 54 and 53 Then, the gate is turned off so that the WR data 65 and the WR gate 66 are not sent to the laser light source driving circuit 56. In this way, the user data can be protected by stopping the recording process when the light spot is positioned on the wrong track during recording.
[0081]
At the time of reproduction, when the ID detection signal 72 is at the “L” level, the controller 801 stops the process of transferring the demodulated data 76 to the host computer or a host device such as a personal computer. As a result, it is possible to prevent erroneous data from being transferred to the host device.
[0082]
When the processing as described above is performed, high reliability can be obtained, but data cannot be read when dust adheres to the ID portion on the medium. Depending on the user, even if dust is attached and the ID cannot be read, there is a case where reproduction is desired even at the expense of some reliability. In such a case, the reproduction process is performed a plurality of times. For example, at the time of the first reproduction, the data can be transferred to the host device and detected on the condition that both the ID1 unit 301 and the ID2 unit 302 can be reproduced correctly. If there is not, the process of transferring the demodulated data 76 to the host apparatus when either one of the ID1 part 301 and the ID2 part 302 can be reproduced at the second and subsequent reproductions, and the ID1 part 301 of the sector to be processed If both ID1 part 301 and ID2 part 302 of one sector or a plurality of previous sectors can be detected even if none of ID2 part 302 can be reproduced, the reproduction process is executed by measuring the timing from the detected sector. May be.
[0083]
In the above description, the same track number is recorded in the track number 308 of the ID1 portion 301 and the ID2 portion 302 of the land 4 shown in FIG. 2, and the tracks of the ID1 portion 301 and the ID2 portion 302 of the groove 5 are recorded. Although different track numbers are recorded in the number 309, different track numbers may be recorded in the track number 309 of the ID1 portion 301 and the ID2 portion 302 of the land 4 or groove 5, respectively. That is, in FIG. 2, the track number of the ID2 portion 302 of the track number 0 land 201 is set to “0”, the track number of the ID1 portion 301 of the track number 0 land 201 is set to “1”, and the ID2 portion of the track number 1 land 203 is set. The track number incremented one by one may be recorded so that the track number of 302 is “2” and the track number of the ID1 portion 301 of the track number 1 land 203 is “3”.
[0084]
On the other hand, in the optical disk apparatus shown in FIG. 3, the optical disk in which the track number is recorded in this way can be dealt with only by changing the settings of the ID1 number instruction value 70 and the ID2 number instruction value 71. In other words, when the track number 0 land 201 is reproduced, the track number “1” is set as the ID1 number instruction value 70 and the track number “0” is set as the ID2 number instruction value 71, so that the land and groove are set. It is possible to distinguish and reproduce a predetermined track in the same manner. The recording and erasing processes can be executed in the same manner.
[0085]
As described above, according to the recording / reproducing apparatus of the present embodiment, adjacent lands and grooves can be distinguished, and erroneous processing can be prevented.
[0086]
Next, a recording / reproducing apparatus according to the second embodiment of the present invention will be described with reference to FIG.
FIG. 6 is a block diagram of an optical disc as a recording / reproducing apparatus according to the second embodiment of the present invention.
[0087]
6, the same reference numerals as those in FIG. 3 denote the same parts, and the configuration and operation thereof are the same as those described in FIG. 3, and thus detailed description thereof is omitted. In the embodiment shown in FIG. 6, the main difference from the embodiment of FIG. 3 is that an ID1CRC arithmetic circuit 93 and an ID2CRC arithmetic circuit 94 are added. With this addition, AND gates 97, 98, and 99 are provided. Note that the optical disk used for recording / reproduction in the recording / reproducing apparatus of the present embodiment has the configuration described with reference to FIGS.
[0088]
The ID1 CRC calculation circuit 93 is reset by the sector pulse 33 (see FIG. 4C) output from the controller 801 at the beginning of the sector. When the ID1 detection gate signal 77 is at the “H” level, the ID1CRC arithmetic circuit 93 takes in the address number 343 of the ID1 portion 301 (see FIG. 4) and the CRC portion 344 in the reproduction signal 31 bit by bit. A predetermined calculation for error detection is performed.
[0089]
Similarly, the ID2 CRC calculation circuit 94 is reset by the sector pulse 33 (see FIG. 4C) output from the controller 801 at the beginning of the sector. The ID2 CRC calculation circuit 94 takes in the address number 347 of the ID2 portion 302 (see FIG. 4) and the CRC portion 348 in the reproduction signal 31 bit by bit when the ID2 detection gate signal 78 is at “H” level. A predetermined calculation for error detection is performed.
[0090]
For example, when the ID1 detection gate signal 77 is at “H” level, the ID1 CRC calculation circuit 93 detects a synchronization mark 307 of the reproduction signal 31 and a predetermined mark after this detection timing. A demodulating circuit that demodulates the address number 312 and the CRC unit 311 recorded by modulation, a shift register that fetches the demodulated address number 312 and the CRC unit 311 for each bit after the detection timing, and the shift register And an arithmetic circuit that performs a predetermined operation corresponding to the generation method of the CRC unit 311 using the output of all bits.
[0091]
Here, as the “predetermined calculation”, for example, 1-bit data obtained by adding all the bits before the modulation of the address number 312 in the mode 2 is inverted, this is modulated, and the CRC section 311, the demodulated address number 312 and all bits of the CRC part 311 are added in mode 2, and when the addition result is an odd number, an “H” level is output. A method of outputting “L” level is used. An error check is performed by reproduction of the CRC unit 311. If no error is detected, an “H” level is output, and if an error is detected, an “L” level is output. Also, other calculation methods may be used.
[0092]
In addition, as the ID1 CRC calculation circuit 93, for example, at the time of reproduction of an ID part including at least an address number and a CRC part 311 for determining whether or not a value obtained by reproducing the address number is correct, an address number is used by using these. Other circuit configurations may be used as long as the circuit outputs a signal that is at the “H” level when it is determined to be correct and holds that level up to the beginning of the next sector.
[0093]
The ID2 CRC calculation circuit 94 uses a configuration similar to that of the ID1CRC calculation circuit 93, and a synchronization mark detection circuit that detects the synchronization mark 307 of the reproduction signal 31 when the ID2 detection gate signal 78 is at "H" level. The demodulating circuit that demodulates the address number 312 and the CRC unit 311 recorded with predetermined modulation after the detection timing, and the demodulated address number 312 and the CRC unit 311 after the detection timing are fetched for each bit. The shift register and an output for each bit of the shift register can be configured by an arithmetic circuit that performs a predetermined operation corresponding to the generation method of the CRC unit 311.
[0094]
The AND gate 97 outputs “H” when the ID1 detection signal 79 is “H” level and the ID1CRC detection signal 111 is “H” level. The AND gate 98 outputs “H” level when the ID2 detection signal 80 is at “H” level and the ID2 CRC detection signal 112 is at “H” level. The AND gate 99 sets the ID detection signal 117 to the “H” level when the output signals of the AND gates 97 and 98 are both at the “H” level.
[0095]
Next, the operation of this embodiment will be described.
If there is no defect in the ID part of the sector to be processed, the ID1 detection signal 79, ID1 detection signal 80, ID1CRC detection signal 111, ID2CRC detection signal 112 are all at “H” level, and the ID detection signal 117 is “H”. "Become level.
[0096]
Therefore, at the time of reproduction, the controller 801 recognizes that the ID has been correctly detected since the ID detection signal 117 becomes “H” level, and demodulates the data of the data section 1 that follows. The user data 118 is transferred to the host device.
[0097]
Further, at the time of recording or erasing, when the ID detection signal 117 becomes "H" level, the AND gates 54 and 53 are turned on, and the WR data 65 and the WR gate 66 are supplied to the laser light source driving circuit 56. Send out and record or erase.
[0098]
If there is a defect in the address portion of the sector to be processed, at least one of the ID1 CRC detection signal 111 and the ID2 CRC detection signal 112 is at “L” level, and the ID detection signal 117 is at “L” level.
[0099]
Therefore, at the time of reproduction, the controller 801 recognizes that the ID cannot be correctly detected because the ID detection signal 117 is at the “L” level, and the user data is not transferred to the host device. Retry if necessary.
[0100]
At the time of recording or erasing, when the ID detection signal 117 becomes "L" level, the AND gates 54 and 53 are turned off, and the WR data 65 and the WR gate 66 are sent to the laser beam driving circuit. Cannot be recorded and recorded or erased. At this time, if necessary, retry may be performed, or if recording, data may be written to another area on the medium.
[0101]
On the other hand, when the address number is erroneously reproduced due to a defect even though it is not a sector to be processed and this matches the address number of the sector to be processed, both the ID1 number detection value 68 and the ID2 number detection value 69 are both Coincides with the ID1 number indication value 70 and the ID2 number indication value 71, respectively, and the ID1 number detection signal 79 and the ID2 number detection signal 80 become “H” level, but the ID1 CRC detection signal 111 and the ID2 CRC detection signal 112 of the ID2 At least one of them becomes “L” level, and the ID detection signal 117 becomes “L” level. As a result, data transfer to the host device is stopped during reproduction, and no processing is performed during recording or erasure, so that it is possible to prevent the data from becoming abnormal.
[0102]
As described above, according to this embodiment, adjacent lands and grooves can be distinguished from each other, so that erroneous processing can be prevented.
[0103]
Even when the address number is reproduced in error, an error check can be performed to prevent erroneous processing.
[0104]
Next, a recording / reproducing apparatus according to a third embodiment of the present invention will be described with reference to FIG.
FIG. 7 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to the third embodiment of the present invention.
[0105]
7, the same reference numerals as those in FIG. 6 denote the same parts, and the configuration and operation are the same as those described in FIG. 6, and thus detailed description thereof is omitted. In the embodiment shown in FIG. 7, the main difference from the embodiment of FIG. 6 is that an arithmetic circuit a127, an arithmetic circuit b128, and a select circuit 130 are added. Along with this addition, comparison circuits 126 and 131 and an AND gate 132 are provided. Note that the optical disk used for recording / reproduction in the recording / reproducing apparatus of the present embodiment has the configuration described with reference to FIGS.
[0106]
The comparison circuit 126 makes a match for each bit except for the ID identification number 309 of the ID1 number detection value 68 detected by the ID1 detection circuit 59 and the ID2 number detection value 69 detected by the ID2 detection circuit 60. The select signal 142 is output at the “H” level at the time of the output and at the “L” level at other times.
[0107]
The arithmetic circuit a127 generates the converted first address number 154 from the ID1 number detection value 68 detected by the ID1 detection circuit 59. The calculation performed by the calculation circuit a127 will be described later.
[0108]
The arithmetic circuit b128 generates the converted second address number 155 from the ID1 number detection value 68 detected by the ID1 detection circuit 59.
[0109]
The select circuit 130 selects the operation circuit a127 side when the select signal 142 output from the comparison circuit 126 is at the “H” level, and selects the operation circuit b128 side when the select signal 142 is at the “L” level.
[0110]
The comparison circuit 131 matches the output of the selection circuit 130 with the ID number indicating value 144 output from the controller 803 for each bit, and outputs a signal 145 that becomes “H” level when all match.
[0111]
The AND gate 129 outputs a signal 143 that becomes “H” level when both the ID1 CRC detection signal 111 output from the ID1CRC arithmetic circuit 93 and the ID2CRC detection signal 112 output from the ID1CRC arithmetic circuit 94 are “H” level. To do.
[0112]
The AND gate 132 outputs the ID detection signal 117 which becomes “H” level when both the signal 145 output from the comparison circuit 131 and the signal 143 output from the AND gate 129 are “H” level.
[0113]
Next, the calculation contents of the arithmetic circuit a127 and the arithmetic circuit b128 will be described.
In the optical disk shown in FIG. 2, there are two sectors, a land and a group, corresponding to the same ID1 number. The arithmetic circuit a127 and the arithmetic circuit b128 distinguish the two sectors to make a unique one. An ID number corresponding to each land and group is generated. For example, in the reproduced ID1 number detection value 68, when the track number is “n”, the arithmetic circuit a127 outputs the converted track number “2n”, and the arithmetic circuit b128 outputs the converted track number “(2n + 1). ) ”, And each sector number is output as it is without being converted.
[0114]
In another type of arithmetic circuit a127 and arithmetic circuit b128, among the reproduced ID1 number detection value 68, the track number is “n” and the maximum value of the track number recorded on the medium is “N”. The arithmetic circuit a127 outputs the converted track number n, the arithmetic circuit b128 outputs the converted track number (N + n), and outputs each sector number as it is without conversion.
[0115]
Further, the arithmetic circuit a127 of another method adds 1 bit as the most significant bit of the reproduced ID1 number detection value 68, sets the most significant pit to “0”, and outputs it. The arithmetic circuit b128 One bit is added as the most significant bit of the reproduced ID1 number detection value 68, and the most significant bit is set to "1" and output.
[0116]
In any case, the arithmetic circuit a127 and the arithmetic circuit b128 discriminate between two sectors corresponding to the same ID1 number, and generate ID numbers corresponding to unique lands and groups, respectively.
[0117]
Next, the operation of this embodiment will be described.
In the optical disk shown in FIG. 2, for the land 4, the track number 308 and sector number 310 of ID1 and the track number 308 and sector number 310 of ID2 are set to the same value. They are set to different values for the block 5. Therefore, the comparison circuit 126 compares the ID1 number detection value 68 detected by the ID1 detection circuit 59 with the ID2 number detection value 69 detected by the ID2 detection circuit 60, and the track number and sector number of the ID1 part and ID2 part are equal. If the sector is determined to be land 4, the output signal 142 of the comparison circuit 126 is at “H” level, and if they do not match and is determined to be group 5, the output signal 142 is at “L” level.
[0118]
Therefore, based on the output signal 142 of the comparison circuit 126, the selector 130 switches between the arithmetic circuit a127 side and the arithmetic circuit b128 side, and the selector 130 outputs the converted ID number corresponding to the land in the land, The group outputs a unique ID number after conversion corresponding to the group.
[0119]
The controller 803 previously sets the ID number of the sector to be processed as the ID number indicating value 144 in a format corresponding to the output of the arithmetic circuit a127 or the arithmetic circuit b128. Accordingly, when the optical head is positioned on the track where the sector exists, tracking is performed, and the laser spot reaches the ID portion of the sector to be processed by the rotation of the medium, it is converted by the arithmetic circuit a127 or the arithmetic circuit b128. The ID number and the ID number instruction value 144 match each other, and the comparison circuit 131 detects that the output signal of the comparison circuit 131 is at the “H” level.
[0120]
As described with reference to FIG. 6, the ID1 CRC calculation circuit 93 and the ID2 CRC calculation circuit 94 perform an error check on the address number, and if the ID1 CRC detection signal 111 and the ID2CRC detection signal 112 become “H” level if they can be reproduced without error, Output.
[0121]
The circuit composed of AND gates 129 and 132 is used when ID1 and ID2 are detected without error by CRC calculation, and the reproduced converted ID number matches the ID number indicating value 144 of the sector to be processed. The ID detection signal 146 of the output becomes “H” level, and the level is held until it is reset by the sector pulse 135 at the head of the next sector.
[0122]
At the time of recording or erasing, the AND gates 54 and 53 are turned on only when the ID detection signal 117 is at "H" level, and the WR data 65 and the WR gate 66 are driven by the laser light source. Send to circuit 56. As a result, if there is an error in the reproduced ID1 number or ID2 number, or if it is different from the sector to be processed, the AND gates 53 and 54 are turned off, the recording and erasing process is stopped, and the user on the optical disk is stopped. Protect the data.
[0123]
During reproduction, the controller 803 transfers the demodulated data 76 to the host device only when the ID detection signal 146 is at “H” level. This prevents erroneous data from being transferred to the host device when the reproduced ID1 number or ID2 number has an error or is different from the sector to be processed.
[0124]
In the present embodiment, the land and group are detected, and the arithmetic circuit a127 and the arithmetic circuit b128 are thereby switched, and the unique ID number (selector) after the conversion regardless of the land and the group is switched. 130 outputs). Therefore, unlike the embodiment shown in FIG. 3 or FIG. 6, it is not necessary to set the ID1 number and the ID2 number separately, and only the ID number indicating value 144 needs to be set. The processing of a microprocessor (not shown) for controlling the processor 803 is simplified.
[0125]
In general, the controller 803 not only performs processing such as ID number instruction by the ID number instruction value 144 described here and generation of an ID1 detection gate, but also, for example, reproduced user data. Is temporarily stored and then transferred to the host device, the user data to be recorded is temporarily stored and then transferred to the laser beam driving circuit, and the memory circuit for adjusting the timing between the host device and the optical disk and its control circuit, A seek control circuit for controlling the optical head unit having means for moving the position of the light spot on the medium of the laser light from the laser light source, and detecting the position of the track where the light spot exists. It is prepared for. If such a method for setting the ID number of the controller 803 is used as the converted ID numbers corresponding to the arithmetic circuit a127 and the arithmetic circuit b128, the logical circuit scale can be reduced, and the controller can be reduced. It is possible to reduce the number of programs for the microprocessor that controls 803.
[0126]
As described above, according to this embodiment, adjacent lands and grooves can be distinguished from each other, so that erroneous processing can be prevented.
[0127]
Even when the address number is reproduced in error, an error check can be performed to prevent erroneous processing.
[0128]
In addition, the processing of the controller is simplified.
[0129]
Further, the circuit scale of the logic circuit can be reduced, and the microprocessor program can be reduced.
[0130]
Next, an information recording medium and a recording / reproducing apparatus using the same according to another embodiment of the present invention will be described with reference to FIGS.
FIG. 8 is a partially enlarged view of the vicinity of a prepit portion on the surface of an optical disc that is an information recording medium according to another embodiment of the present invention.
[0131]
The configuration of the recording track of the optical disk in this embodiment is the same as that of the embodiment described in FIG. 1, and the same reference numerals as those in FIG.
[0132]
The ID unit 2 includes an ID1 unit 301, an ID2 unit 302, an ID3 unit 303, an ID4 unit 304, and a sector mark unit 305. The pre-pit 7 is arranged on the lower side in the figure with respect to the center line of the land 4 in the ID1 part 301, the ID3 part 303, and the sector mark 305, and the ID2 part 302 and the ID4 part 304 with respect to the center line of the land 4 It is arranged on the upper side in the figure. The ID1 portion 301 and the ID2 portion 302 are arranged at different positions in the circumferential direction (track direction) of the optical disc, and the ID3 portion 303 and the ID4 portion 304 are arranged in the circumferential direction (track direction) of the optical disc. Are arranged at different positions.
[0133]
Similar to the ID1 unit 301 and ID2 unit 302 described with reference to FIG. 2, the ID3 unit 303 and ID4 unit 304 include a VFO unit 306, a synchronization mark 307, an address number 312, and a CRC unit 311, respectively. Yes.
[0134]
The same track number is recorded in the track number 308 of the ID1 part 301, ID2 part 302, ID3 part 303, and ID4 part 304 of the land 4. That is, for example, the track number “1” is recorded in the ID1 portion 301 of the track number 1 land 183, and the same track number “1” is also recorded in the ID2 portion 302, the ID3 portion 303, and the ID4 portion 304. .
[0135]
On the other hand, ID1 part 301 and ID3 part 303 of group 5 share pre-pit 7 with land 4 on the upper side in the figure, and ID2 part 302 and ID4 part 304 share pre-pit with land 4 on the lower side in the figure. Shared. Therefore, the track numbers of the ID1 part 301 and ID3 part 303 of the group 5 are different from the track numbers of the ID2 part 302 and the ID4 part 304, and are the most different track numbers. That is, for example, the track number “0” is recorded in the ID1 portion 301 and the ID3 portion 303 of the track number 0 group 182, and the track number “1” is recorded in the ID2 portion 302 and the ID4 portion 304. Yes.
[0136]
That is, in this embodiment, the address number is recorded four times for one track consisting of the land 4 or the groove 5.
[0137]
Of the address numbers 312, the ID identification number 309 records information for identifying the ID1 part 315, the ID2 part 316, the ID3 part 317, and the ID4 part 318. For example, the ID1 part 301 has "00". Is recorded in the ID2 section 302, "10" is recorded in the ID3 section 303, and "11" is recorded in the ID2 section 304.
[0138]
The information recording medium according to the present embodiment can reduce the track offset and the crosstalk.
[0139]
Further, by providing a plurality of identical ID portions, an information recording medium resistant to defects is obtained.
[0140]
Next, a recording / reproducing apparatus according to the fourth embodiment of the present invention will be described with reference to FIG.
FIG. 9 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to the fourth embodiment of the present invention.
[0141]
9, the same reference numerals as those in FIG. 3 denote the same parts, and the configuration and operation thereof are the same as those described in FIG. 3, and thus detailed description thereof is omitted. 9 is different from the embodiment of FIG. 3 in that an ID3 detection circuit 82, an ID4 detection circuit 83, a comparison circuit 88, and a comparison circuit 89 are added. With this addition, OR gates 410 and 411 are provided. Note that the optical disc used for recording / reproducing in the recording / reproducing apparatus of the present embodiment has the configuration described with reference to FIGS.
[0142]
The controller 804 outputs a sector pulse 33, an ID1 detection gate signal 77, an ID2 detection gate signal 78, an ID3 detection gate signal 84, and an ID4 detection gate signal 85.
[0143]
The sector pulse 33 is output at the VFO part in the ID1 part 301 of the reproduction signal with the timing of the sector mark detection signal 81 as a reference. The ID1 detection gate signal 77 is a gate signal that becomes “H” level in the area of the internal synchronization mark, address number, and CRC portion of the ID1 portion 301. Further, the ID2 detection gate signal 78 is a gate signal which becomes “H” level in the area of the internal synchronization mark, address number and CRC part of the ID2 part 302.
[0144]
Further, the ID3 detection gate signal 84 is a gate signal that becomes “H” level in the area of the inner synchronous mark, the address number, and the CRC portion of the ID3 portion 303. The ID4 detection gate signal 85 is a gate signal that becomes "H" level in the area of the inner sync mark, address number, and CRC part of the ID4 part 304.
[0145]
The ID1 detection circuit 59 is reset by the sector pulse 33, detects the ID number during the period when the ID1 detection gate signal 77 is at the “H” level, and outputs the ID1 number detection value 68 to the comparison circuit 62. The ID2 detection circuit 60 is reset by the sector pulse 33, detects the ID number during the period when the ID2 detection gate signal 78 is at “H” level, and outputs the ID2 number detection value 69 to the comparison circuit 63.
[0146]
The ID3 detection circuit 82 is reset by the sector pulse 33, detects the ID number during the period when the ID3 detection gate signal 84 is at the “H” level, and outputs the ID3 number detection value 90 to the comparison circuit 88.
[0147]
The ID4 detection circuit 83 is reset by the sector pulse 33, detects the ID number during the period when the ID4 detection gate signal 85 is at the “H” level, and outputs the ID4 number detection value 91 to the comparison circuit 89.
[0148]
The controller 804 designates the track number of the sector on which processing such as reproduction, recording, or erasure is executed by the ID1 · 3 indication value 86 and the ID2 · 4 indication value 87.
[0149]
The comparison circuits 62, 63, 88, 89 respectively detect the ID1 number detection value 68 and the ID1 / 3 indication value 86, and match the ID2 number detection value 69 with the ID2 / 4 indication value 87, thereby detecting the ID3 number. The value 90 is matched with the ID1 · 3 indication value 86, and the ID4 number detection value 91 and the ID2 · 4 indication value 87 are matched for each bit. When all the bits match, ID1 detection that becomes “H” level is detected. A signal 434, an ID2 detection signal 435, an ID3 detection signal 436, and an ID4 detection signal 437 are output.
[0150]
When either the ID1 detection signal 434 or the ID3 detection signal 436 is at “H” level, the output signal 427 of the OR gate 410 becomes “H” level, and either of the ID2 detection signal 435 or ID4 detection signal 437 is “H”. At the “level”, the output signal 428 of the orage 411 is at the “H” level.
[0151]
When both the output signal 427 and the output signal 428 are at the “H” level, the ID detection signal 429 that is the output of the AND gate 412 is at the “H” level, indicating that the sector to be processed can be detected. . The ID detection signal 429 is sent to the controller 804, reports the ID detection status, and is sent to the AND gates 54 and 53.
[0152]
On the other hand, the controller 804 is at the “H” level at the write (WR) data 65 which is data to be recorded on the optical disc when the recording process is executed, and at the data portion of the reproduction signal 31 when the recording or erasing process is executed. WR gate 66 which is a gate signal to be sent to AND gates 54 and 53, respectively. At the time of recording or erasing, the laser light source driving circuit 56 is controlled by the output signals of the AND gates 54 and 53, and the laser power of the laser light source 57 is recorded at the timing of erasing or marking. Enhance the recording to erase or record.
[0153]
At the time of reproducing ID or data, the data to be recorded is not output to the WR data 65, and the WR gate 66 is turned off, so that the laser light source driving circuit 56 is at the time of recording or erasing. The laser light source 57 emits light that is relatively weak as compared with the above. Further, the demodulating circuit 75 demodulates the reproduction signal 31 of the user data recorded by performing predetermined modulation on the data section 1 on the optical disk, and sends it to the controller 804.
[0154]
The controller 804 is provided with a modulation circuit for performing predetermined modulation on user data to be recorded on the optical disk, and the modulated data is output as WR data 65. As a modulation method, 1-7 RLL modulation, 2-7 RLL modulation, or the like may be used. However, the modulation circuit in the controller 804 and the demodulation circuit 75 are configured to correspond to the same modulation method.
[0155]
Next, the ID1 · 3 instruction value 86 and the ID2 · 4 instruction value 87 output from the controller 804 will be described.
[0156]
When recording, reproduction, and erasing of the optical disk configured as described with reference to FIG. 8, the land 4 corresponds to the land that performs processing with the ID1 · 3 instruction value 86 and the ID2 · 4 instruction value 87. Set the same track number. For group 5, different track numbers corresponding to the group to be processed are set in ID1 · 3 instruction value 86 and ID2 · 4 instruction value 87, respectively. In group 5, the track numbers of ID2 portion 302 and ID4 portion 304 are set to a value larger by one track than the track numbers of ID1 portion 301 and ID3 portion 303, corresponding to ID portion 2 of FIG. The ID1 / 3 instruction value 86 set in this way matches any of the ID1 number detection value 68 and ID3 number detection value 90, and the ID2 / 4 instruction value 87, ID2 number detection value 69, and ID4 number. It is detected by using the comparison circuits 62, 63, 88, 89, orage gates 410, 411, and AND gate 412 that any one of the detected values 91 matches, and the processing is executed on this condition.
[0157]
For example, the ID3 detection circuit 82 and the ID4 detection circuit 83 have the same circuit configuration as the ID1 detection circuit 59 or the ID2 detection circuit 60 described in FIG. As detection gates corresponding to the ID1 portion 301, ID2 portion 302, ID3 portion 303, and ID4 portion 304, an ID1 detection gate 77, an ID2 detection gate 78, an ID3 detection gate 84, and an ID4 detection gate. -The four gate signals of the gate 85 are used, and the ID is detected by distinguishing them according to the timing.
[0158]
Next, the operation of the optical disc apparatus according to the fourth embodiment of the present invention will be described with reference to FIG.
FIG. 10 is a time chart at the time of recording in the optical disc apparatus according to the fourth embodiment of the present invention.
[0159]
FIG. 10 is an enlarged view of the timing of the ID part when recording is performed on the sector of sector number “4” of the track number 2 group 186 of the optical disk shown in FIG.
[0160]
FIGS. 10A to 10E correspond to FIGS. 4A to 4E, respectively, and FIGS. 10H and 10I correspond to FIGS. 4F and 4G, respectively. 10 (S) to (V) correspond to FIGS. 4 (M) to (P), respectively.
[0161]
The sector mark 314 of the reproduction signal 31 is detected, and a pulse signal is output to the sector mark detection signal 81. Using the detection pulse as a reference, the controller 804 outputs a pulse signal of the sector pulse 33 in the vicinity of the VFO unit 321, while a gate signal indicating the region of the synchronous mark 322, address number 323, and CRC unit 324. An ID1 detection gate signal 77, a synchronization mark 326, an address number 327, an ID2 detection gate signal 78 which is a gate signal indicating the area of the CRC unit 328, a synchronization mark 330, and an address number 331, an ID3 detection gate signal 84 which is a gate signal indicating the area of the CRC section 332, an ID4 detection gate which is a gate signal indicating the area of the synchronous mark 334, the address number 335, and the CRC section 336. -Output a signal 85.
[0162]
FIG. 10F shows a gate signal ID3 detection gate signal 84 output from the controller 804 shown in FIG. The controller 804 outputs the ID3 detection gate signal 84 that is at the “H” level in the areas of the synchronous mark 330, the address number 331, and the CRC unit 332 with reference to the detection pulse of the sector mark detection signal 81.
[0163]
FIG. 10G shows the gate signal ID2 detection gate signal 85 output from the controller 804 shown in FIG. The controller 804 outputs an ID4 detection gate signal 85 which becomes “H” level in the area of the synchronous mark 334, the address number 335 and the CRC unit 336 with reference to the detection pulse of the sector mark detection signal 81.
[0164]
Further, as shown in FIGS. 10L and 10M, the controller 804 sets the address of the sector to be processed to the ID1 · 3 instruction value 86 and the ID2 · 4 instruction value 87. The ID1 · 3 instruction value 86 and the ID2 · 4 instruction value 87 are set to the timing before the ID part of the sector is detected when processing of one sector is performed. When processing a plurality of sectors in succession, the ID number of the head of the processing sector is set, and after the processing of the head sector, the sector number is set to 1 at the timing of the sector pulse 33 from the second sector onward. Increase it step by step.
[0165]
As shown in FIG. 10 (H), the ID1 number detection value 68 is reset by the pulse signal of the sector pulse 33, and then the ID1 part address number 323 is set during the period when the ID1 detection gate 77 is at the “H” level. For example, the track number “2” and the sector number “4” are set.
[0166]
As shown in FIG. 10I, the ID2 number detection value 69 is reset by the pulse signal of the sector pulse 33, and then the ID2 part address number 327 is set during the period when the ID2 detection gate 78 is at the “H” level. The read values, for example, track number “3” and sector number “4” are set and held until the timing of the pulse signal of sector pulse 33 of the next sector.
[0167]
As shown in FIG. 10J, after the ID3 number detection value 90 is reset by the pulse signal of the sector pulse 33, the ID3 part address number 331 is read during the period when the ID3 detection gate 84 is at "H" level. The values, for example, track number 2 and sector number 4 are set and held until the timing of the pulse signal of the sector pulse 33 of the next sector.
[0168]
As shown in FIG. 10 (K), after the ID4 number detection value 91 is reset by the pulse signal of the sector pulse 33, the ID4 part address number 335 is read while the ID4 detection gate 85 is at "H" level. For example, the track number “3” and the sector number “4”, which are the values, are set and held until the timing of the pulse signal of the sector pulse 33 of the next sector.
[0169]
As the ID1 number detection value 68, the ID2 number detection value 69, the ID3 number detection value 90, and the ID4 number detection value 91 when reset by the sector pulse 33, for example, as shown in FIGS. Although the track number “0” and the sector number “0” may be set, the ID may be erroneously detected when the processing of the sector having the track number “0” and the sector number “0” on the medium is executed. Therefore, it is more desirable to set the track number and sector number to a number that cannot exist on the medium.
[0170]
As shown in FIG. 10 (N), when the track number “2” and the sector number “4” are set in the ID1 number detection value 68, the ID1 detection signal 434 matches the ID1 / 3 indication value 86, It becomes “H” level.
[0171]
As shown in FIG. 10 (O), when the track number 3 and sector number 4 are set in the ID2 number detection value 69, the ID2 detection signal 435 matches the ID2 · 4 indication value 87 and becomes “H” level. Become.
[0172]
As shown in FIG. 10 (P), when the track number 2 and the sector number 4 are set to the ID3 number detection value 90, the ID3 detection signal 436 matches the ID1 · 3 indication value 86 and becomes “H” level. It becomes.
[0173]
On the other hand, as shown in FIG. 10 (Q), when track number 3 and sector number 4 are set to ID4 number detection value 91, ID4 detection signal 437 matches ID2 · 4 indication value 87 and is “H”. Become a level.
[0174]
The ID1 detection signal 434 and the ID3 detection signal 436, and the ID2 detection signal 435 and the ID4 detection signal 437 are all at the “H” level in the area including all the data portions that follow, and the ID detection signal 429 generated from them is also As shown in FIG. 10 (R), the level becomes “H” level.
[0175]
When the ID detection signal 429 becomes "H" level during recording or erasing, the AND gates 54 and 53 are turned on, and the WR data 65 and the WR gate 66 output from the controller 804 are connected to the AND gate 54. , 53 to the laser beam driving circuit for recording or erasing.
[0176]
At the time of reproduction, when the ID detection signal 429 is at the “H” level, the data recorded in the data section is used as the demodulated data 81 from the controller section 804 to the host computer or personal computer. Transfer to device.
[0177]
Next, the operation when a defect occurs on the optical disc will be described with reference to FIGS.
FIG. 11 is a waveform diagram of a reproduction signal reproduced from an optical disc according to another embodiment of the present invention shown in FIG.
[0178]
In FIG. 11, the track number 0 land reproduction signal 191 schematically shows a signal reproduced from the track number 0 land 181 shown in FIG. 8, and the track number 0 groove reproduction signal 192 is shown in FIG. A signal reproduced from the track number 0 groove 182 is schematically shown. Other reproduction signals 193,..., 200 are also reproduction signals corresponding to the lands 183,..., 189 and grooves 184,.
[0179]
Here, for example, when a defect 904 occurs as shown in FIG. 8, the track number 3 group reproduction signal 198 shown in FIG. Therefore, the address signal of the ID2 unit 302 cannot be correctly reproduced. On the other hand, the track number “3” is reproduced from the ID1 portion 301 and the ID3 portion 303, which is the same value as the ID1 and ID3 of the track number 3 land 197, and thus cannot be distinguished from each other.
[0180]
However, although the ID2 portion is defective and cannot be reproduced correctly, the track number “4” is reproduced from the ID4 portion 304 having no defect. As shown in FIG. 11, a track whose ID number 301 or ID3 303 has a track number of “3” and whose track number of ID2 302 or ID4 304 is “4” can be seen. 11, only the track number 3 group reproduction signal 198 of FIG. 11 corresponding to the track number 3 group 188 of FIG.
[0181]
Therefore, even if there is at most one defect such as the defect 904 in the ID portion 2, the track can be identified, and the optical disc apparatus shown in FIG. 9 can execute the recording, reproducing, and erasing processes. That is, the ID2 detection signal 435 corresponding to the defective ID2 unit 302 is at “L” level, but the other ID1 detection signal 434, ID3 detection signal 436, and ID4 detection signal 437 are at “H” level. Become. As a result, the output 427 of the OR gate 410 and the output 428 of the OR gate 411 are set to the “H” level, the ID detection signal 429 output from the AND gate 412 is set to the “H” level, and recording, reproduction, and erasing are performed. Execute the process.
[0182]
As described above, the optical disc apparatus according to the present embodiment using the optical disc in which the address number is recorded a plurality of times on one side of the track boundary and the address number is recorded a plurality of times on the other boundary is provided on the one side of the track. At least one of the address numbers recorded a plurality of times can be detected, and at least one of the address numbers recorded a plurality of times on the other side of the track can be detected. Since the process is performed by specifying, even if there are a predetermined number of defects or less in the address numbers recorded a plurality of times, the defect is strong against the defect that can specify the sector.
[0183]
For example, when defects 902 and 903 are generated as shown in FIG. 8, the track number 1 group reproduction signal 194 shown in FIG. 922 and 923 occur, and the address signals of ID2 and ID4 cannot be reproduced correctly. The track number “1” is reproduced from the ID1 portion 301 and the ID3 portion 303, which is the same value as the ID1 and ID3 of the track number 1 land 193, and cannot be distinguished from each other.
[0184]
If the track number 1 group 184 is recorded or erased only on the condition that it matches the track number designated by the ID1 part 301 or ID3 part 303, the optical head is positioned on the track number 1 land 183 by mistake. This cannot be detected, and data already recorded in the track number 1 land 183 is destroyed.
[0185]
If the same thing occurs during data reproduction, the data of the track number 1 land 183 different from the requested one is transferred.
[0186]
In this embodiment, ID1, ID2, ID3, and ID4 are individually detected by the detection gate in order to prevent malfunction caused by a defect formed on the optical disc, and any one of ID1 and ID3 is the indicated value. Recording, erasing, reproduction, and the like are performed on condition that they match and either ID2 or ID4 matches the indicated value.
[0187]
That is, in the present embodiment, when the process of the track number 1 group 184 of the optical disk shown in FIG. 8 is executed, “1” is set as the track number in the ID1 / 3 instruction value 86 and the ID2 / 4 instruction value is set. 87 is set to “2” as the track number. At this time, if the track number 1 land 183 is mistakenly positioned, the track number “1” is detected by the ID1 detection circuit 59 and the ID3 detection circuit 82, and the ID1 detection signal 434 matches the ID1 · 3 indication value 86. The ID3 detection signal 436 becomes “H” level. On the other hand, the track number “1” is detected by the ID2 detection circuit 60 and the ID4 detection circuit 83, but the track number “2” is set in the ID2 • 4 indication value 87, so that the comparison circuits 63 and 89 match. Instead, the ID2 detection signal 435 and the ID4 detection signal 437 are at the “L” level. Although the output signal 427 of the OR gate 410 is at the “H” level, the output signal 428 of the OR gate 411 is at the “L” level because neither ID 2 nor ID 4 is detected. The ID detection signal 429 generated by ANDing the output signal 427 and the output signal 428 becomes “L” level and reports to the controller 804 that the ID could not be detected normally. In 54 and AND gate 53, the gate is turned off so that WR data 65 and WR gate 66 are not sent to laser light source driving circuit 56.
[0188]
In this way, when the light spot is positioned on the wrong track during recording, the recording process is stopped to protect the user data. Further, at the time of reproduction, when the ID detection signal 429 is at “L” level, the controller 804 stops the process of transferring the demodulated data 81 to the host device. This prevents erroneous data from being transferred to the host device.
[0189]
As described above, in the optical disc as shown in FIG. 8, when both ID1 and ID3 or both ID2 and ID4 cannot be reproduced correctly, the sector cannot be specified. In such a case, the ID detection signal 429 is It becomes "L" level, and it is possible to prevent the data in the wrong sector from being transferred to the host device without transferring the demodulated data 76.
[0190]
As described above, according to this embodiment, adjacent lands and grooves can be distinguished from each other, so that erroneous processing can be prevented.
[0191]
Since the address number is recorded a plurality of times, the sector can be specified even if the address number recording portion is defective.
[0192]
Next, a recording / reproducing apparatus according to the fifth embodiment of the present invention will be described with reference to FIG.
FIG. 12 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to the fifth embodiment of the present invention.
[0193]
12, the same reference numerals as those in FIG. 9 denote the same parts, and the configuration and operation thereof are the same as described in FIG. 9, and thus detailed description thereof is omitted. In the embodiment shown in FIG. 12, the main difference from the embodiment of FIG. 9 is that an ID1CRC arithmetic circuit 93, an ID2CRC arithmetic circuit 94, an ID3CRC arithmetic circuit 95, and an ID4CRC arithmetic circuit 96 are added. With this addition, AND gates 453, 454, 455, 456, 459 and OR gates 457, 458 are provided. Note that the optical disc used for recording / reproducing in the recording / reproducing apparatus of the present embodiment has the configuration described with reference to FIGS.
[0194]
The ID1 CRC calculation circuit 93 is reset by the sector pulse 33 output from the controller 804 at the beginning of the sector. When the ID1 detection gate 77 is at "H" level, the address number and CRC part of the ID1 part of the reproduction signal 31 are fetched bit by bit, and a predetermined calculation for error detection is performed.
[0195]
Similarly, the ID2 CRC calculation circuit 94 is reset by the sector pulse 33 output from the controller 804 at the beginning of the sector. When the ID2 detection gate 78 is at "H" level, the address number and CRC part of the ID2 part of the reproduction signal 31 are fetched bit by bit and predetermined calculation is performed.
[0196]
The ID3 CRC calculation circuit 95 is reset by the sector pulse 33 output from the controller 804 at the beginning of the sector. Then, when the ID3 detection gate 84 is at "H" level, the address number of the ID3 part and the CRC part of the reproduction signal 31 are fetched bit by bit and predetermined calculation is performed.
[0197]
The ID4 CRC calculation circuit 96 is reset by the sector pulse 33 output from the controller 804 at the beginning of the sector. Then, when the ID4 detection gate 85 is at "H" level, the address number and CRC part of the ID4 part of the reproduction signal 31 are fetched bit by bit and predetermined calculation is performed.
[0198]
For example, when the ID1 detection gate 77 is at “H” level, the ID1CRC arithmetic circuit 93 detects a synchronization mark 307 of the reproduction signal 31 and a predetermined modulation after this detection timing. , A demodulating circuit that demodulates the recorded address number 312 and the CRC unit 310, a shift register that fetches the demodulated address number 312 and the CRC unit 310 for each bit after the detection timing, and the shift register The output for each bit is configured by an arithmetic circuit that performs a predetermined operation corresponding to the configuration method of the CRC unit 311.
[0199]
Here, as the “predetermined calculation”, for example, 1-bit data obtained by adding all the bits before the modulation of the address number 312 in mode 2 is inverted, and this is modulated, and the CRC section 311, the demodulated address number 312 and all bits of the CRC unit 311 are added in mode 2, and when the addition result is an odd number, an “H” level is output. A method of outputting “L” level is used. That is, when the address number and the ID part having at least the CRC part 311 for judging whether or not the reproduced value of the address number is correct, the address number is checked by using these and the result is judged to be correct. In other words, a signal that becomes “H” level is output and the level is held until the beginning of the next sector.
[0200]
The ID2CRC arithmetic circuit 94, ID3CRC arithmetic circuit 95, and ID4CRC arithmetic circuit 96 use ID2 detection gate 78, ID3 detection gate 84, and ID4 detection gate 85 as detection gates, respectively. The calculation is performed with distinction according to the timing, but the other configuration is the same as that of the ID1CRC calculation circuit 93.
[0201]
The AND gate 453 outputs "H" when the ID1 detection signal 434 is at "H" level and the ID1CRC detection signal 513 is at "H" level. The AND gate 454 outputs “H” when the ID2 detection signal 435 is at “H” level and the ID2 CRC detection signal 514 is at “H” level. The AND gate 455 has an output of “H” level when the ID3 detection signal 436 is at “H” level and the ID3 CRC detection signal 515 is at “H” level. The AND gate 456 outputs "H" when the ID4 detection signal 437 is at "H" level and the ID4CRC detection signal 516 is at "H" level.
[0202]
Further, the output of the OR gate 457 is at the “H” level when any one of the outputs of 453 and 455 is at the “H” level. The output of the OR gate 458 becomes “H” level when any of the outputs of 454 and 456 is “H” level. In the AND gate 459, when both the outputs of the OR gate 457 and the OR gate 458 are at "H" level, the ID detection signal 502 of the output becomes "H" level.
[0203]
Next, the operation of this embodiment will be described.
If there is no defect in the ID part of the sector to be processed, the ID1 detection signal 434, the ID2 detection signal 435, the ID3 detection signal 436, the ID4 detection signal 437, the ID1CRC detection signal 513, the ID2CRC detection signal 514, the ID3CRC detection signal 515, The ID3 CRC detection signals 516 are all at the “H” level. As a result, the ID detection signal 502 becomes “H” level.
[0204]
Therefore, at the time of reproduction, the controller 804 recognizes that the ID has been correctly detected because the ID detection signal 502 becomes “H” level, and transfers the demodulated user data 76 to the host device. .
[0205]
Further, at the time of recording or erasing, when the ID detection signal 502 becomes “H” level, the AND gates 54 and 53 are turned on, and the WR data 65 and the WR gate 66 are supplied to the laser light source driving circuit 56. Send out and record or erase.
[0206]
For example, if there is a defect in the address portion of ID1 of the sector to be processed, the ID1 detection signal 434 and the ID1CRC detection signal 513 are both at the “L” level, but other ID2 detection signals 435 and ID3 detection signals 436 , ID4 detection signal 437, ID2CRC detection signal 514, ID3CRC detection signal 515, ID4CRC detection signal 516 are at "H" level, and ID detection signal 502 is at "H" level, thereby recording and reproducing data. Can be erased. In the optical disk shown in FIG. 8, address information is recorded twice each in a prepit provided at the boundary with the upper track in the figure from the center of the track and a prepit provided at the boundary with the lower track. In the optical disc apparatus according to the present embodiment, the sector is specified on the condition that the data has been correctly reproduced at least once. For this reason, in this embodiment, even if there is at most one defect in the ID part, the sector can be specified from other IDs and the process can be executed.
[0207]
On the other hand, for example, there are a plurality of defects in the ID part, and the sector is not a sector to be processed, but the address number is erroneously reproduced due to the defect. For example, a sector in which the ID1 number detection value 68 and the ID2 number detection value 69 are processed Even if it coincides with the address number of ID1, the ID1 detection signal 434 and the ID2 detection signal 435 are at the “H” level, but the ID1CRC detection signal 513 and the ID2CRC detection signal 514 remain at the “L” level due to a defect, and the ID1 and ID2 Indicates that it is incorrect. Since ID3 and ID4 are normally reproduced and are not sectors to be processed, they do not match in comparison circuit 88 and comparison circuit 89, and ID3CRC detection signal 515 and ID4CRC detection signal 516 are both at "H" level, but ID3 detection Both the signal 436 and the ID4 detection signal 437 are at the “L” level. Accordingly, the outputs of the AND gates 453, 454, 455, and 456 are all at "L" level, and as a result, the ID detection signal 502 is at "L" level. As a result, data transfer to the host device is stopped during reproduction, and no processing is performed during recording or erasure, so that it is possible to prevent a data abnormality.
[0208]
As described above, in the present embodiment, even when the address information is erroneously reproduced due to a defect, the validity of the address information is determined by using the check code recorded in the CRC section. By checking the reproduction signals of both the prepits at the boundary with the adjacent track on the upper side in the figure and the prepits on the lower side in the figure, address information errors are detected and the data is protected.
[0209]
As described above, according to this embodiment, adjacent lands and grooves can be distinguished from each other, so that erroneous processing can be prevented.
[0210]
Since the address number is recorded a plurality of times, the sector can be specified even if the address number recording portion is defective.
[0211]
Even when the address number is reproduced in error, an error check can be performed to prevent erroneous processing.
[0212]
Next, a recording / reproducing apparatus according to the sixth embodiment of the present invention will be described with reference to FIGS.
FIG. 13 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to the sixth embodiment of the present invention.
[0213]
13, the same reference numerals as those in FIG. 12 denote the same parts, and the configuration and operation are the same as those described in FIG. 12, and thus detailed description thereof is omitted. In the embodiment shown in FIG. 13, the main difference from the embodiment of FIG. 12 is that an arithmetic circuit a101, an arithmetic circuit b102, an arithmetic circuit a103, an arithmetic circuit b104, a select circuit 130, and a switching condition setting circuit 119 are added. It is in. Along with this addition, a comparison circuit 121 is provided. Note that the optical disc used for recording / reproducing in the recording / reproducing apparatus of the present embodiment has the configuration described with reference to FIGS.
[0214]
The arithmetic circuit a101 generates the converted first address number 554 from the ID1 number detection value 68. The calculation performed by the calculation circuit a101 will be described later.
[0215]
The arithmetic circuit b102 generates the converted second address number 555 from the ID1 number detection value 68.
[0216]
The arithmetic circuit a103 generates the converted third address number 566 from the ID3 number detection value 90.
[0217]
The arithmetic circuit b104 generates the converted fourth address number 567 from the ID3 number detection value 90.
[0218]
The selector circuit 120 switches the first address number 554, the second address number 555, the third address number 566, the fourth address number 567, and the GND 556 after the conversion from the switching condition setting circuit 119. It switches by 553.
[0219]
The switching condition setting circuit 119 includes an ID1 number detection value 68, an ID2 number detection value 69, an ID3 number detection value 90, an ID4 number detection value 91, an ID1CRC detection signal 513, an ID2CRC detection signal 514, an ID3CRC detection signal 515, and an ID4CRC detection signal. Based on the value of 516, the switching signal 553 is generated according to the conditions shown in FIG.
[0220]
The comparison circuit 121 detects the coincidence between the output signal 557 of the selection circuit 120 and the ID number instruction value 558 output from the controller 806, and when the coincidence is detected, the output becomes “H” level.
[0221]
Next, calculation contents of the arithmetic circuit a101, the arithmetic circuit b102, the arithmetic circuit a103, and the arithmetic circuit b104 will be described.
In the optical disk shown in FIG. 8, there are two sectors, a land and a group, corresponding to the same ID1 number. The arithmetic circuit a101 and the arithmetic circuit b102 distinguish each of the two sectors to make each unique. ID numbers corresponding to lands and groups are generated. Similarly, there are two sectors, a land and a group, corresponding to the same ID3 number. The arithmetic circuit a103 and the arithmetic circuit b104 distinguish each of the two sectors into a unique land and group, respectively. A corresponding ID number is generated. For example, when the track number is “n” in the reproduced ID1 number detection value 68 or ID3 number detection value 90, the arithmetic circuits a101 and 103 output the converted track number “2n” and the arithmetic circuit b102. , 104 outputs the converted track number “(2n + 1)”, and outputs each sector number without conversion.
[0222]
In another type of arithmetic circuit, among the reproduced ID1 number detection value 68 or ID3 number detection value 90, the track number is “n” and the maximum track number recorded on the medium is “N”. ", The arithmetic circuits a101 and 103 output the converted track number" n ", the arithmetic circuits b102 and 104 output the converted track number" (N + n) ", and the sector numbers are Output as is without conversion.
[0223]
In another type of arithmetic circuit, the arithmetic circuits a101 and 103 add one bit as the most significant bit of the reproduced ID1 number detection value 68 and ID3 number detection value 90, and use it as the most significant bit. “0” is set and output, and the arithmetic circuits b102 and 104 add one bit as the most significant bit of the reproduced ID1 number detection value 68 and ID3 number detection value 90, and set “1” to the most significant bit. Set and output.
[0224]
Next, the switching condition of the selector circuit 120 output from the switching condition setting circuit 119 will be described with reference to FIG.
FIG. 14 is an explanatory diagram of the switching conditions of the selector circuit in the recording / reproducing apparatus according to the sixth embodiment of the present invention.
[0225]
In the optical disk shown in FIG. 8, in the land 4, the track numbers of the ID1 part 301 and the ID3 part 303, the ID2 part 302 and the ID4 part 304 are set to the same value, and in the group 5, the track numbers are set to different values. Has been.
[0226]
Accordingly, the switching condition setting circuit 119 determines that the track is a land when the track numbers of the ID1 portion 301 or ID3 portion 303 and the ID2 portion 302 or ID4 portion 304 match, and if they do not match, -It is determined that
[0227]
On the other hand, since the ID number to be reproduced may be erroneously read due to a defect or the like, the converted ID number is generated using the ID number detection value determined to be normal from the CRC calculation result.
[0228]
That is, the switching condition setting circuit 119 can determine that the ID is normal based on the CRC calculation result of at least one of ID1 and ID3 and any ID of ID2 and ID4. If any of ID1 and ID3 where the signal has become “H” level and either ID2 or ID4 match, it is determined to be a land, and if they do not match, it is determined to be a group.
[0229]
When the switching condition setting circuit 119 determines that it is a land, the selector circuit 120 selects the output signal of the arithmetic circuit a101 or 103 by the switching signal 553, and when it is determined that it is a group, the selector circuit 120 outputs the output signal of the arithmetic circuit b102 or 104. Select. When both ID1 and ID3 or both ID2 and ID4 cannot be normally detected from the CRC calculation result, it is determined that the sector ID detection is invalid, and the selector circuit 120 selects the GND 556.
[0230]
When it is determined as a land, the selector circuit 120 outputs the outputs of the arithmetic circuit a101 that generates the converted ID number from the ID1 number detected value 68 and the arithmetic circuit a103 that generates the converted ID number from the ID3 number detected value 90. Of these, the one determined to be normal from the CRC calculation result is selected. If both IDs are normal, either may be used, but in the example shown in FIG. 14, the arithmetic circuit a101 is set to have priority.
[0231]
On the other hand, when it is determined that the group is selected, the selector circuit 120 selects one of the outputs of the arithmetic circuits b102 and 104, which is determined to have a normal ID from the CRC calculation result. If both IDs are normal, either may be used, but in the example shown in FIG. 14, the arithmetic circuit b102 is set to have priority.
[0232]
In this manner, the selector circuit 120 switches between the arithmetic circuits a101 and 103 and the arithmetic circuits b102 and 104, and the selector circuit 120 outputs the converted ID number corresponding to the land in the land and the group in the group. -Output the converted ID number corresponding to
[0233]
The controller 806 previously sets the ID number of the sector to be processed in the comparison circuit 121 as an ID number indicating value 558 in a format corresponding to the output of the arithmetic circuits a101 and 103 or the arithmetic circuits b102 and 104. When the optical head is positioned and tracked on the track where the sector exists and the laser spot is moved to the ID portion of the sector to be processed by the rotation of the optical disk, the selector output 557 and the ID number indicating value 558 match. The ID detection signal 559 detected by the circuit 121 becomes “H” level.
[0234]
At the time of recording or erasing, only when the ID detection signal 559 is at "H" level, the AND gates 54 and 53 are turned on, and the WR data 65 and the WR gate 66 are driven by the laser light source. Send to circuit 56. As a result, when the reproduced ID1 number and ID3 number, or both ID2 number and ID4 number 4 have errors due to defects, etc., and the land and group cannot be identified, or when the sector is different from the sector to be processed Turns off the AND gates 54 and 53 to stop the recording and erasing process to protect the user data on the medium.
[0235]
Further, at the time of reproduction, the controller 806 transfers the demodulated data 560 to the host device only when the ID detection signal 559 is at “H” level. As a result, when the reproduced ID1 number and ID3 number, or both ID2 number and ID4 number 4 have errors due to defects, etc., and the land and group cannot be identified, or when the sector is different from the sector to be processed Therefore, it is possible to prevent erroneous data from being transferred to the host device.
[0236]
Further, in the present embodiment, the land and group are detected, and the arithmetic circuits a101 and 103 and the arithmetic circuits b102 and 104 are thereby switched, and after the unique conversion regardless of the land and group. An ID number 557 is generated. Therefore, unlike the embodiment shown in FIG. 9 or FIG. 12, it is not necessary to set the ID1 number and ID3 number, and the ID2 number and ID4 number separately, and only the ID number instruction value 558 needs to be set. The processing of the controller 806 or the microprocessor that controls the controller 806 is simplified.
[0237]
In general, the controller 806 not only performs an ID number instruction by the ID number instruction value 558 described here and generation of an ID1 detection gate, but also reproduces the reproduced user data, for example. After temporarily storing it, it is transferred to the host device, the user data to be recorded is temporarily stored and then transferred to the laser beam driving circuit, and the memory circuit for adjusting the timing between the host device and the optical disk and its control circuit, A seek control circuit that controls at least an optical head unit having means for moving a spot position where a laser beam from a laser light source is connected to the medium, and detects a track position on the optical disc; Composed. If such a method for setting the ID number of the controller 806 is used as the ID numbers after conversion corresponding to the arithmetic circuits a101 and 103 and the arithmetic circuits b102 and 104, the logic circuit scale can be reduced. The number of programs for the microprocessor that controls the controller 806 can be reduced.
[0238]
As described above, according to this embodiment, adjacent lands and grooves can be distinguished from each other, so that erroneous processing can be prevented.
[0239]
Since the address number is recorded a plurality of times, the sector can be specified even if the address number recording portion is defective.
[0240]
Even when the address number is reproduced in error, an error check can be performed to prevent erroneous processing.
[0241]
In addition, the processing of the controller is simplified.
[0242]
Further, the circuit scale of the logic circuit can be reduced, and the microprocessor program can be reduced.
[0243]
In each of the above-described embodiments, the optical disk shown in FIGS. 2 and 8 shows an example in which the sector mark 305 is provided at the head of the ID section 2, but the sector mark is shown. The present invention can also be applied when no is provided. When the present invention is applied to an optical disk without a sector mark, the head pulse of the ID part 2 of the reproduction signal is detected instead of the sector mark detection circuit 61 of each embodiment, and a detection pulse is output at the detected timing. Use a circuit that
[0244]
If there is an area in which no signal is recorded between the end of the data section 1 and the head of the ID section 2, the reproduction signal is at the “L” level for a predetermined time instead of the sector mark detection circuit 61. By detecting this, this no-signal area is detected, and a circuit that outputs a detection pulse at the detected timing, or when this no-signal area is detected and the first pulse is detected, the first pulse is detected It is also possible to use a circuit that outputs detection pulses at the same timing.
[0245]
The circuits described above are all circuits that detect the head of the ID section 2, but a circuit that can be used in place of the sector mark detection circuit is not limited to this. In short, it can be used as a reference for each gate signal output from the controllers 801, 803, 804, and 806 in synchronization with the sector composed of the ID portion 2 and the data portion 1 in synchronization with the signal reproduced from the optical disk. Any circuit that outputs a signal may be used. For example, a circuit that detects the synchronization mark 307 of the ID unit 2 and outputs a detection pulse at the detected timing can be used.
[0246]
In the optical disk shown in FIG. 2 and FIG. 8, information to be assigned to the pre-pits at the boundary between the land and the group includes the VFO unit 306, the sync mark 307, the track number 308, the ID identification number 309, the sector number 310, And the CRC part 311, at least a pre-pit including the track number and the CRC part may be provided at the boundary between the land and the group, and other information is provided at the boundary between the land and the group. It does not have to be provided. That is, the VFO unit 306, the sync mark 307, the ID identification number 309, and the sector number 310 can be set to the same pit pattern in the adjacent land and group, and the pit pattern is the same. The crosstalk is negligible, and there is no need to provide it at the boundary. The present invention can be applied to such a medium as long as the track number and the CRC portion are provided at the boundary between the land and the group as shown in FIG. 2 or FIG.
[0247]
Further, in the land of the ID part 2 shown in FIG. 8, the prepits of the ID1 part 301 and the ID3 part 303 are arranged at the boundary with the lower group in the figure, and the upper group in the figure The ID2 portion 302 and ID4 portion 304 pre-pits are arranged at the boundary between them, but the present invention is not limited to such a recording medium, and can be used for other recording media. For example, in the land, the ID1 part and ID2 part prepits are arranged at the boundary with the lower group, and subsequently the ID3 part and ID4 part prepits are arranged at the upper boundary. Can do.
[0248]
In the present invention, the sector position is specified by independently detecting the address information included in the prepit provided on one side of the track boundary and the address information included in the prepit provided on the other side. Yes, even if the order or number of the two changes, the present invention can be used by providing a corresponding detection circuit.
[0249]
In the above-described embodiment, the same track number is assigned to the ID1 part and ID2 part prepits arranged above and below the same land of the information recording medium. However, the present invention is not limited to this. That is, a medium in which the combination of ID numbers reproduced from the prepits on the upper and lower boundaries of a track is different from the combination of ID numbers reproduced from the prepits on the upper and lower boundaries of an adjacent track. Any medium can be used. That is, when the ID1 number instruction value and the ID2 number instruction value in the recording / reproducing apparatus can be set independently, the combination of ID numbers can be freely set.
[0250]
In each of the embodiments described above, the ID identification number 309 is not particularly used, and the present invention can be applied to a medium without an ID identification number. Further, the order of the track number 308, the ID identification number 309, the sector number 310, and the CRC unit 311 is not limited to that shown in the figure, and may be set in any manner.
[0251]
Further, in the optical discs shown in FIGS. 2 and 8, a track number 308 that is a radial address and a sector number 310 that is a circumferential address are provided to identify a sector. Absent. The present invention can also be applied to a configuration in which address numbers are sequentially assigned by one numerical value instead of two numerical values of a track number and a sector number.
[0252]
For example, a groove is set in a spiral shape and data is recorded on both the land and the groove formed by the groove, and the land address numbers (ID1 and ID2) are from the outer periphery to the inner periphery. When the pre-pit is provided at the boundary between the land and the groove in the same manner as in FIG. 2, when the apparatus shown in FIG. In the land, the same address number corresponding to the address number setting method is set as the ID1 number indicating value 70 and the ID2 number indicating value 71. In the group, the difference between the ID1 number indicating value and the ID2 number indicating value is one track. It may be set so as to correspond to the number of sectors.
[0253]
In each of the above-described embodiments, for convenience of explanation, the gate widths of the ID1 detection gate signal, ID2 detection gate signal, ID3 detection gate signal, and ID4 detection gate signal are set to ID1, ID2, ID3. , And an ID4 synchronous mark 307, an address number 312 and an area including a CRC part 311, but are not limited thereto. That is, any timing may be set as long as it is a gate signal that can be detected exclusively by distinguishing ID1, ID2, ID3, and ID4.
[0254]
For example, a register circuit for fetching the reproduced address number at the end is provided for each of ID1, ID2, ID3, and ID4, and a pulse serving as a trigger for fetching each ID1 detection gate signal, ID2 detection gate signal, ID3 When the detection gate signal and the ID4 detection gate signal are distinguished and taken into the respective registers, the width of each detection gate signal is set as long as it is wider than the trigger pulse. May be. That is, in the present invention, any setting may be used as long as each detection gate can distinguish and detect a plurality of IDs provided in one sector.
[0255]
In each of the above-described embodiments, the ID1 detection gate signal, the ID2 detection gate signal, the ID3 detection gate signal, and the ID4 detection gate signal are used, but the present invention uses these. Not necessary. That is, these detection gate signals are used for distinguishing the address numbers where these signals are reproduced from the difference in the relative positions of ID1, ID2, ID3, and ID4 with respect to the reference signal generated from the reproduced signal. Similarly, any method may be used as long as ID1, ID2, ID3, and ID4 are distinguished by using the difference in timing at which they are located in the reproduction signal.
[0256]
In the above-described methods, all the IDs are distinguished by using the timing differences of ID1, ID2, ID3, and ID4 in the reproduction signal. However, the present invention is not limited to this, and the ID identification number 309 is not limited to this. If it is provided, it may be distinguished by reproducing it.
[0257]
In each embodiment, the ID1 detection circuit, the ID2 detection circuit, the ID3 detection circuit, and the ID4 detection circuit are shown as independent circuits in order to simplify the description. Some circuits may be shared, and the present invention is not limited thereby.
[0258]
Similarly, some of the ID1 CRC calculation circuit, the ID2 CRC calculation circuit, the ID3 CRC calculation circuit, and the ID4 CRC calculation circuit may be shared, and the present invention is not limited thereby.
[0259]
The other circuits are also shown as examples, and the present invention is not limited thereto.
[0260]
Moreover, although the block diagrams showing the respective embodiments are all described as hardware configurations, some or all of the functions can be configured as software.
Furthermore, the present invention is a recording medium that performs high density recording with a narrow track pitch, and records a relatively large mark on the ID portion and a relatively small mark on the data portion. If the recording medium and the recording / reproducing apparatus are provided so that the mark of the ID section is arranged on the boundary or the boundary extension line of the track and the mark is not present on both sides of the track at the same time, The present invention can be used not only for optical disks but also for optical disks using systems other than land / group recording, single spiral optical disks, and optical disks in which tracks are arranged concentrically. For example, the user data is recorded only in the group, the user data is not recorded in the land, and the land width is relatively narrower than that of the group to increase the density. When an optical disk and a relatively large prepit including address information are arranged in the center of the land and shared by two adjacent groups, two tracks (groups) sharing the prepit are Can be used to identify.
[0261]
Further, for example, in a magnetic disk device or a magnetic tape device, when a relatively large mark is recorded in the ID portion compared to the user data area, the mark in the ID portion is adjacent. This can be used when two tracks are shared.
[0262]
Here, when the above-described embodiment is applied to a recording medium in which one spiral method or tracks are concentrically arranged, the expressions “land” and “group” are used in the drawings of the embodiment and the description thereof, for example, even-numbered numbers. It can be read as an expression such as a track and an odd-numbered track. In addition, when the following embodiment is applied to a two-spiral system other than land / group recording, the expressions “land” and “group” are referred to as, for example, a first spiral and a second spiral. It can be read as an expression.
[0263]
In addition, any data recording mark may be used when an optical disk is used as the recording medium. For example, two types of states having different reflectivities due to phase changes on the medium may be used. A phase change recording method to be formed or a magneto-optical recording method for detecting a color rotation angle of reflected light may be used.
[0264]
Also, any method can be used as the pre-pit portion for recording the ID information, but a mechanical hole is formed on the medium to detect the difference in reflectance between the portion with and without the hole. A drilling method may be used.
[0265]
The recording medium is divided into sectors each composed of an ID portion and a data portion, which are recording units, and recording / reproducing on the recording medium is performed in units of sectors.
[0266]
Further, each of the above-described embodiments has been described with reference to an example of an optical disk as an information recording medium, and an example of an optical disk apparatus as a recording / reproducing apparatus using the information recording medium. However, the information recording medium includes address information. Any mark having a mark between a track and an adjacent track can be applied to a recording medium other than an optical disk, and can also be applied to a recording / reproducing apparatus as well as a recording / reproducing apparatus other than an optical disk apparatus. .
[0267]
【The invention's effect】
According to the present invention, the information recording medium can be a high-density type with a narrow track pitch, and the track can be distinguished.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a recording track of an optical disc that is an information recording medium according to an embodiment of the present invention.
FIG. 2 is a partially enlarged view in the vicinity of a prepit portion on the surface of an optical disc according to an embodiment of the present invention.
FIG. 3 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to an embodiment of the present invention.
FIG. 4 is a time chart at the time of recording in the optical disc apparatus according to the embodiment of the present invention.
FIG. 5 is a waveform diagram of a reproduction signal reproduced from the optical disc according to the embodiment of the present invention shown in FIG. 2;
FIG. 6 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to a second embodiment of the present invention.
FIG. 7 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to a third embodiment of the present invention.
FIG. 8 is a partially enlarged view of the vicinity of a pre-pit portion on the surface of an optical disc that is an information recording medium according to another embodiment of the present invention.
FIG. 9 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to a fourth embodiment of the present invention.
FIG. 10 is a time chart at the time of recording in the optical disc apparatus according to the fourth embodiment of the present invention.
11 is a waveform diagram of a reproduction signal reproduced from an optical disc according to another embodiment of the present invention shown in FIG.
FIG. 12 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to a fifth embodiment of the present invention.
FIG. 13 is a block diagram of an optical disc apparatus which is a recording / reproducing apparatus according to a sixth embodiment of the present invention.
FIG. 14 is an explanatory diagram of switching conditions of a selector circuit in an optical disc device that is a recording / reproducing device according to a sixth embodiment of the present invention.
[Explanation of symbols]
1 ... Data part, 2 ... ID part, 4 ... Land
5 ... Group, 6 ... Record mark, 7 ... Prepit
10 ... optical disc, 31 ... reproduction signal, 33 ... sector pulse
56 ... Laser beam drive circuit, 57 ... Laser light source, 58 ... Light receiving part
59... ID1 detection circuit, 60... ID2 detection circuit
61 ... Sector mark detection circuit, 62, 63, 88, 89, 121 ... Comparison circuit
75 ... Demodulation circuit, 82 ... ID3 detection circuit, 83 ... ID4 detection circuit
93 ... ID1CRC arithmetic circuit, 94 ... ID2CRC arithmetic circuit
95 ... ID3CRC arithmetic circuit, 96 ... ID4CRC arithmetic circuit
101, 102, 103, 104, 127, 128 ... arithmetic circuit
120, 130 ... selector circuit
801, 802, 804, 806 ... Controller

Claims (6)

In an information recording medium provided with a plurality of sectors on land tracks and groove tracks,
The plurality of sectors have an address information area and a data area,
The address information area has a plurality of address parts,
The plurality of address portions are a first address portion provided at a boundary portion between left and right land tracks and groove tracks, and a boundary portion between the left and right adjacent land tracks and groove tracks provided with the address portions. And a second address portion provided at a boundary portion adjacent to the left and right,
In the plurality of address portions, each of the first address portion and the second address portion has the same address information area as a portion in which information indicating a position of the own sector of the plurality of sectors is recorded. And a part in which information for identifying the self address part is recorded from other address parts included therein,
A first land track, a first groove track adjacent to the first land track, a second land track adjacent to the first groove track, and a second land track adjacent to the second land track. Information indicating the position of the own sector in the first address portion provided at a boundary portion between the first land track and the first groove track, in the plurality of address portions in the groove track , Information indicating the position of the sector in the second address portion provided at the boundary between the first groove track and the second land track, and the second land track and the second groove track. the information indicating the position of the local sector in the first address part provided in the boundary portion, only sequentially one track bets Information recording medium comprising a click is information indicating different. The information recording medium according to claim 1,
An information recording medium, wherein a plurality of the first address part and the second address part are provided in the same address information area. The information recording medium according to claim 1 or 2,
The land track and the groove track are divided into a plurality of tracks in the radial direction of the information recording medium,
Each of the plurality of tracks is divided into N sectors in the circumferential direction of the information recording medium. The information recording medium according to claim 3, wherein
The portion in which the information indicating the position of the own sector is recorded indicates the track information portion in which information indicating the position in the radial direction of the own information recording medium is recorded, and the position in the circumferential direction of the own information recording medium An information recording medium comprising a sector information section on which information is recorded. The information recording medium according to any one of claims 1 to 4,
The information recording medium is characterized in that the address information area is recorded in a plurality of prepits. The information recording medium according to any one of claims 1 to 5,
The information recording medium is characterized in that the plurality of address portions are recorded in a plurality of prepits provided at a boundary portion between a land track and a groove track adjacent to each other on the left and right.

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